Bile salts regulate ion transport in the intestine of Senegalese sole (original) (raw)
Related papers
Characteristics of ionic transport processes in fish intestinal epithelial cells
Biosystems, 1998
A general mathematical version of the cell model of a leaky epithelium for the NaCl absorption is presented, analysed and integrated numerically. The model consists in the adequate differential equations that describe the rate of change of the intracellular ion concentrations and are expressed in strict accordance with the law of mass conservation. The model includes many state variables representing ion concentrations, the cell volume, and membrane potentials. Ion movements are described by the Michaelis -Menten kinetics or by the constant field flux equation (Goldman-Hodgkin-Katz). In this paper, we model the intracellular ion concentrations, change in the cell volume, the transmembrane flux and membrane potentials of intestinal epithelium of both fresh water and sea water fish, and generate several simulations (in both the steady state and the transient state analysis) that appear to accord with prior experimental data in this area. For the ion movements of the sea water fish intestine, there were included a Na + /K + pump, a K + -Cl − symport system, the K + and Cl − channels in the basolateral membrane, whereas a Na + -K + -2Cl − cotransporter for NaCl absorption and K + channels are located in the apical membrane. In the fresh water fish intestinal cells, the NaCl absorption is performed by two coupled antiporters Na + /H + and Cl − /HCO 3 − presumably responsible for the intracellular pH regulation. In this type of cells, Na + and K + channels are located within the apical membrane, whereas Cl − channels are located within the basolateral membrane. The osmotically induced water transport across the apical and basolateral membranes has been taken into account as well. The simulations plot the steady state values for membrane potential difference, short-circuit current and intracellular ionic concentrations using the magnitude of the transmembrane flux through the Na + /K + pump and Na + -K + -2Cl − cotransporter, or the basolateral Cl − permeability as dependent variables. The model behaves appropriately with regard to several experimental studies regarding the hyperpolarization (sea water fish intestine) and depolarization (fresh water fish intestine) of the apical membrane potential and inhibition of the short-circuit flux with reduced NaCl absorption. The model is also used to make several analytical predictions regarding the response of the membrane potential and ionic concentrations to variations in the basolateral Cl − flux. Furthermore, maintaining PII S 0 3 0 3 -2 6 4 7 ( 9 7 ) 0 0 0 7 1 -3 L. Mo6ileanu et al. / BioSystems 45 (1998) 123-140 124 conservation of both mass and electroneutrality and taking into account the osmolar forces is an important advantage, because it allows a rigorous analysis of the relationship between membrane potential difference, volume and flux. The model can be used in the analysis and planning of the experiments and is capable of predicting the instantaneous values of ionic fluxes and intracellular concentrations and of cell volume.
Transport of bile acids in a human intestinal epithelial cell line, Caco-2
Biochimica et Biophysica Acta (BBA) - General Subjects, 1990
The transport of tanrocholic acid (TA) across Caco-2 cell monolayers was dependent on time in culture and reached a plateau after 28 days, at which time the apical (AP)-to-basolateral (131,) transport was 10-times greater than BL-to-AP transport. The amounts of TA inside the cells following application of 10 nM [I4C]TA to tile AP or BL side of the monolayers (30 min) were approximately equal (54.4 + 2.7 and 64.6 ± 2.8 fmol/mg protein, respectively). AP-to-BL transport of TA was saturable and temperature-dependent. Vm~ , and K m for transport were 13.7 pmol / mg protein per min and 49.7 pM, respectively. The transport of TA had an activation energy of 13.2 kcal-mo1-1, required Na + and glucose. AP-to-BL transport of |14C]TA was inhibited by the co-administration (on the AP side) of either unlabeled TA or deoxycholate, but it was not reduced by the presence of unlabeled TA on the BL side.
Bile salt-associated electrolyte secretion
Experimental and Toxicologic Pathology, 1992
The mechanisms involved in bile salt-induced choleresis are poorly known. To give an insight in this physiological process, bile salt-associated electrolyte secretion was studied following relief of a short-term (2 h) biliary .obstruction in the rat, an experimental model that shows an important diminution of bile salt choleretic efficiency. For this purpose, biliary excretion of total bile salts and electrolytes (sodium, chloride and bicarbonate) were studied in such a model during taurocholate infusion at increasing rates. The results showed that bile flow, bile salt output and electrolyte secretion stimulated by taurocholate,administration were decreased in the rats that were subjected to biliary obstruction. Besides, the choleretic efficiency of the excreted bile salts, as estimated by the slope of the regression line of bile flow vs. bile salt output, was diminished by 46 % (p < 0.005). Multiple regression analysis of bile flow vs. bile salt and electrolyte outputs allowed to detect a selective diminution of the fraction of bile flow related to bile salt-associated electrolyte secretion ("secretory fraction" of the choleretic efficiency of bile salts) (3.2 ± 0.3 vs. 2.5 ± 0.2L1mol, p < 0.05) whereas the "osmotic fraction" of the choleretic efficiency of bile salts was not modified by the treatment (5. a ± 0.4 vs. 5.1 ± 0.3 Llmol, p> 0.05). Since both chloride and bicarbonate biliary concentrations in the volume of bile stimulated by taurocholate were reduced by 53 % and 52 % respectively, a role of these anions in the generation of bile salt-induced choleresis was suggested. Possible mechanisms involved in such a process and in its early impairment during cholestasis are discussed.
Sensitivity of bile acid transport by organic anion-transporting polypeptides to intracellular pH
Biochimica et Biophysica Acta (BBA) - Biomembranes, 2003
We investigated the influence of intracellular pH (pHi) on [ 14 C]-glycocholate (GC) uptake by human hepatoblastoma HepG2 cells that express sodium-independent (mainly OATP-A and OATP-8), but not sodium-dependent, GC transporters. Replacement of extracellular sodium by choline (Chol) stimulated GC uptake but did not affect GC efflux from loaded cells. Amiloride or NaCl replacement by tetraethylammonium chloride (TeACl) or sucrose also increased GC uptake. All stimulating circumstances decreased pHi. By contrast, adding to the medium ammonium or imidazole, which increased pHi, had no effect on GC uptake. In Chinese hamster ovary (CHO) cells expressing rat Oatp1, acidification of pHi had the opposite effect on GC uptake, that is, this was reduced. Changes in extracellular pH (pHo) between 7.40 and 7.00 had no effect on GC uptake at pHi 7.30 or 7.45 when pHo < pHi. However, GC uptake was inhibited at pHo 7.40 and 7.80 when pHo>pHi. Inhibition was not proportional to the pHo À pHi difference. Intracellular acidification decreased V max , but had no effect on K m. In sum, sodium-independent GC transport can be affected by intracellular acidification, possibly due both to modifications in the driving forces and to the particular response to protonation of carrier proteins involved in this process.
Pflügers Archiv - European Journal of Physiology, 2014
Bile acids play important physiological role in the solubilisation and absorption of dietary lipids. However, under pathophysiological conditions, such as short bowel syndrome, they can reach the colon in high concentrations inducing diarrhea. In this study our aim was to characterise the cellular pathomechanism of bile-induced diarrhea using human samples. Colonic crypts were isolated from biopsies of patients (controls with negative colonoscopic findings) and of cholecystectomised/ileumresected patients with or without diarrhoea. In vitro measurement of the transporter activities revealed impaired Na+/H+ exchanger (NHE) and Cl-/HCO3-exchanger (CBE) activities in cholecystectomised/ileum-resected patients suffering from diarrhea, compared to control patients. Acute treatment of colonic crypts with 0.3mM chenodeoxycholate caused dose-dependent intracellular acidosis; moreover, the activities of acid/base transporters (NHE and CBE) were strongly impaired. This concentration of chenodeoxycholate did not cause morphological changes in colonic epithelial cells, although significantly reduced the intracellular ATP level, decreased Powered by Editorial Manager® and ProduXion Manager® from Aries Systems Corporation mitochondrial transmembrane potential and caused sustained intracellular Ca2+ elevation. We also showed that chenodeoxycholate induced Ca2+ release from the endoplasmic reticulum and extracellular Ca2+ influx contributing to the Ca2+ elevation. Importantly, our results suggest that the chenodeoxycholate induced inhibition of NHE activities was ATP-dependent, whereas the inhibition of CBE activity was mediated by the sustained Ca2+ elevation. We suggest that bile acids inhibit the function of ion transporters via cellular energy breakdown and Ca2+ overload in human colonic epithelial cells, which can reduce fluid and electrolyte absorption in the colon and promote the development of diarrhea.